A high-speed data transfer protocol for geostationary orbit satellites

2016 International Conference on Advanced Technologies for Communications (ATC) Pub Date : 2016-10-01 DOI:10.1109/ATC.2016.7764819

K. Murata, P. Pavarangkoon, Kenji Suzuki, Kazunori Yamamoto, T. Asai, T. Kan, N. Katayama, M. Yahata, K. Muranaga, Takamichi Mizuhara, Ayahiro Takaki, E. Kimura

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引用次数: 7

Abstract

In communication systems using geostationary orbit satellites, throughput of transmission control protocol (TCP) is limited due to the impact of latency on network and packet loss caused by signal attenuation in severe weather conditions like heavy rain. It is high time to develop network techniques and applications in broadband communications over the gigabit satellite and the high throughput satellite (HTS). In this paper, we introduce a high-speed data transfer protocol, named high-performance and flexible protocol (HpFP), to achieve high throughput over a geostationary satellite link even in severe weather conditions. The HpFP is firstly evaluated on a laboratory experiment simulating a geostationary orbit satellite link. It is clarified that the HpFP shows high throughputs even when the packet loss ratio (PLR) is 0.01%. We next carry out a field experiment using the Wideband InterNetworking engineering test and Demonstration Satellite (WINDS). The performance of the HpFP over single, dual, and multiple connections are evaluated. The result shows that the aggregate throughput of dual connections of HpFP almost reaches to the maximum bandwidth, and the time to the maximum bandwidth is within 3 sec which is over 20 times faster than that by the TCP. For multiple connections, the HpFP shares the bandwidth equally among all 50 connections.

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地球静止轨道卫星的高速数据传输协议

在使用地球静止轨道卫星的通信系统中，由于网络延迟的影响以及暴雨等恶劣天气条件下信号衰减造成的丢包，传输控制协议(TCP)的吞吐量有限。发展千兆卫星和高通量卫星宽带通信网络技术和应用已刻不容眉睫。在本文中，我们引入了一种高速数据传输协议，称为高性能和灵活协议(HpFP)，即使在恶劣天气条件下，也能在地球静止卫星链路上实现高吞吐量。首先在模拟地球静止轨道卫星链路的实验室实验中对HpFP进行了评估。说明即使丢包率(PLR)为0.01%，HpFP也显示出高吞吐量。接下来，我们将使用宽带互联网络工程测试和演示卫星(WINDS)进行现场实验。评估了HpFP在单、双、多连接下的性能。结果表明，HpFP双连接的总吞吐量几乎达到最大带宽，达到最大带宽的时间在3秒内，比TCP快20倍以上。对于多个连接，hhpfp在所有50个连接中平均共享带宽。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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2016 International Conference on Advanced Technologies for Communications (ATC)

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